磁场效应下平板上低普朗特数流体的边界层流动和对流传热的解析解

IF 2.8 Q2 THERMODYNAMICS Heat Transfer Pub Date : 2024-05-07 DOI:10.1002/htj.23072
Ajay Kumar Agrawal, Yogesh Gupta
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引用次数: 0

摘要

本研究旨在量化外加磁场影响下水平平板上的流场、流速和传热特征,尤其侧重于低普朗特数流体。非线性偏微分表达式可以通过适当的变换纳入常微分框架。本研究利用变分迭代法(VIM)来近似求解定义问题的非线性微分方程系统。与其他方法相比,其目的是证明 VIM 在解决传热问题方面具有更高的灵活性和更广泛的应用。将 VIM 得出的结果与数值解进行了比较,结果表明近似解的精确度非常高。数值结果有力地表明,VIM 可以有效地为非线性微分方程提供精确的数值解。分析包括对不同参数下的流场、速度和温度分布的检查。研究发现,增加普朗特数对改善温度模式、速度分布和流动动力学都有积极影响。因此,这会导致边界层厚度减小,并改善运动表面的热传递。因此,对流过程变得更加有效。当磁场强度增加时,流体的速度会降低。这一观察结果与预期一致,因为磁场会阻碍对流的自然流动。值得注意的是,对流过程可以通过小心施加磁力来精确控制。
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Analytical solution to boundary layer flow and convective heat transfer for low Prandtl number fluids under the magnetic field effect over a flat plate

The present study aims to quantify the flow field, flow velocity, and heat transfer features over a horizontal flat plate under the influence of an applied magnetic field, with a particular emphasis on low Prandtl number fluids. Nonlinear partial differential expressions can be incorporated into the ordinary differential framework with the use of appropriate transformations. This research utilizes the variational iteration method (VIM) to approximate solutions for the system of nonlinear differential equations that define the problem. The objective is to demonstrate superior flexibility and broader application of the VIM in addressing heat transfer issues, compared to alternative approaches. The results obtained from the VIM are compared with numerical solutions, revealing a significant level of accuracy in the approximation. The numerical findings strongly suggest that the VIM is effective in providing precise numerical solutions for nonlinear differential equations. The analysis includes an examination of the flow field, velocity, and temperature distribution across various parameters. The study found that improving temperature patterns, velocity distribution, and flow dynamics were all positively impacted by increasing the Prandtl numbers. As a result, this leads to the thickness of the boundary layer to decrease and improves heat transfer at the moving surface. Thus, the convection process becomes more efficient. When the strength of the magnetic field is increased, the velocity of the fluid decreases. This observation aligns with expectations since the magnetic field hampers the natural flow of convection. Notably, the convection process can be precisely controlled by carefully applying magnetic force.

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来源期刊
Heat Transfer
Heat Transfer THERMODYNAMICS-
CiteScore
6.30
自引率
19.40%
发文量
342
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